Accretion-Driven Turbulence in the Circumgalactic Medium
Abstract
Simulations suggest that turbulence is ubiquitous in the circumgalactic medium (CGM), though the source and properties of CGM turbulence is uncertain. Using analytic considerations and hydrodynamic simulations we study how CGM turbulence is driven by gas accretion, thus providing a baseline for additional turbulence driving processes such as galaxy feedback. We demonstrate that in halos with mass 1010-1012 M at 0 < z < 2, accretion amplifies mild turbulent velocities near the virial radius of σt(R vir) 10 \, km \, s-1 to virial velocities at inner CGM radii, σt(0.1 R vir) ≈ v vir 100 \, km \, s-1. Rapid cooling at these inner radii further implies that thermal pressure support is small, and the gas is dominated by the cool and warm ( 104-105 \, K) phases. Inner CGM energetics in these halos is thus dominated by turbulence, with gas density distributions and velocity structure functions similar to those seen in simulations of isothermal supersonic turbulence, rather than those seen in subsonically turbulent stratified media such as the ICM. The accretion rate in these systems is regulated by the turbulence dissipation rate, in contrast with being regulated by the cooling rate as in more massive halos. We argue that galaxy feedback is unlikely to qualitatively change our conclusions unless it significantly depletes the CGM or continuously injects high specific energy material ( v2 vir). Such `turbulence-dominated' CGM can be identified in observations via the predicted wide lognormal ionization distributions and large velocity dispersions in UV absorption spectra.
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